ライフサイエンスコーパス: battery

1 antly influence the specific capacity of the battery.

2 on battery and the carbon-enhanced lead-acid battery.

3 istered computerized neuropsychological test battery.

4 ated with printed electrochromic display and battery.

5 development of an all-solid-state magnesium battery.

6 on, and the Penn Computerized Neurocognitive Battery.

7 water through the membranes when cycling the battery.

8 ent species using the same cognitive ability battery.

9 uli during performance of the Emotional Test Battery.

10 esponding voltage ranges, in a lithium-based battery.

11 overcome in realizing a practical magnesium battery.

12 challenging surface chemistry issue in Li-S batteries.

13 ergy densities exceeding that of lithium-ion batteries.

14 mising high energy densities for lithium-ion batteries.

15 r and rectified outputs ready for serving as batteries.

16 with potential applications in aluminum-ion batteries.

17 sions on the role of water and its impact on batteries.

18 lacement for lithium metal in Li-O2 and Li-S batteries.

19 ls to enable the next-generation high-energy batteries.

20 application of high-energy-density Li metal batteries.

21 rage systems including lithium sulfur (Li-S) batteries.

22 -dendritic nature of Mg deposition in Mg ion batteries.

23 fer to operate than nonaqueous lithium-based batteries.

24 ent of robust, fully operational solid-state batteries.

25 y-density cathode materials in lithium-based batteries.

26 s, all-solid-state air batteries, and hybrid batteries.

27 modern technology in the form of lithium-ion batteries.

28 on reaction (OER) in fuel cells or metal-air batteries.

29 when compared with conventional lithium-ion batteries.

30 cle-life electrodes for organic rechargeable batteries.

31 s and for enabling high-performance Li-metal batteries.

32 efficient air electrode catalysts in Zn-air batteries.

33 ) is ever increasing, which calls for better batteries.

34 raditional graphite materials in lithium-ion batteries.

35 c Li dendrites and build safe solid Li-metal batteries.

36 storage applications, such as lithium-sulfur batteries.

37 bility issue and failure mechanism of Mg ion batteries.

38 ne vehicles and do not require large plug-in batteries.

39 safety and rate capabilities of lithium-ion batteries.

40 r the performances of rechargeable metal-air batteries.

41 uels with much greater energy densities than batteries.

42 node materials design in high-energy-density batteries.

43 echnologies such as fuel cells and metal-air batteries.

44 esign of materials for practical multivalent batteries.

45 g them attractive for low-cost, energy-dense batteries.

46 to produce viable Si-C composites for Li-ion batteries.

47 plied as an active electrode in rechargeable batteries.

48 ntial in the development of renewable Li-ion batteries.

49 and sodium-ion batteries, and lithium-sulfur batteries.

50 batteries and next-generation lithium metal batteries.

51 cantly improving the cycle stability of Li-S batteries.

52 as a promising anode material for sodium ion batteries.

53 l additives for future lithium-sulfur (Li-S) batteries.

54 is investigated as an anolyte for redox-flow batteries.

55 plications ranging from nanomanufacturing to batteries.

56 tion reaction (HER) to cathode materials for batteries.

57 n (OER), is a critical process for metal-air batteries.

58 rinciples for photo-rechargeable lithium ion batteries.

59 ors, detectors, energy harvesting cells, and batteries.

60 y cathode materials in practical lithium-ion batteries.

61 ve energy storage devices beyond lithium-ion batteries.

62 nsic redox reactions to develop rechargeable batteries.

63 ng the application of graphene in commercial batteries.

64 cost, high-performance anode for lithium ion batteries.

65 o realize all solid state lithium (Li) metal batteries.

66 -HUST-4 as an anode material in a sodium-ion battery achieving an excellent discharge capacity of 467

67 h are widely employed in all-solid-state ion batteries, all-solid-state air batteries, and hybrid bat

68 l to the stability of rechargeable metal-air batteries, an issue that is gaining increasing interest

69 the performance of animals on cognitive test batteries analogous to those of humans?

70 important electrode material for lithium-ion batteries and a model system for studying electrochemica

71 n the lithiation process used in lithium ion batteries and also offers potential benefits for applica

72 a wide variety of applications, ranging from batteries and fuel cells to chemical sensors, because th

73 vantages of photoelectrochemical devices and batteries and has emerged as an attractive alternative t

74 uge benefit to both the existing lithium-ion batteries and next-generation lithium metal batteries.

75 omplish flexible and stretchable lithium-ion batteries and supercapacitors are reviewed.

76 Cambridge Neuropsychological Test Automated Battery and a planning task.

77 Participants completed a neuropsychological battery and neuroimaging that included optimized magneti

78 ons in energy storage devices such as li-ion battery and supercapacitor.

79 ergy-storage devices such as the lithium-ion battery and the carbon-enhanced lead-acid battery.

80 al current both in the dark (as a 'solar bio-battery') and in response to light (as a 'bio-solar-pane

81 hysical function (Short Physical Performance Battery) and depressive symptoms (Patient Health Questio

82 Composite of the MATRICS Consensus Cognitive Battery) and secondary outcomes (the MATRICS Attention-V

83 lid-state ion batteries, all-solid-state air batteries, and hybrid batteries.

84 chemical capacitors, lithium- and sodium-ion batteries, and lithium-sulfur batteries.

85 y technologies such as fuel cells, metal-air batteries, and water electrolyzers.

86 evice could operate for 10 min via a printed battery, and display the result for many hours or days.

87 impairments in working memory on a CogState battery; and (3) psychotomimetic effects measured by the

88 product can be used as high-capacity Li-ion battery anode materials with excellent cycling performan

89 As a lithium ion battery anode, our multi-phase lithium titanate hydrates

90 orage anolyte for aqueous organic redox flow battery (AORFB) applications.

91 nstrate a neutral aqueous organic redox flow battery (AORFB) technology utilizing a newly designed ca

92 mposite spheres toward practical lithium-ion battery applications.

93 This battery architecture gradually integrates controlled amo

94 Sodium ion batteries are being considered as an alternative to lith

95 Lithium-ion batteries are crucial to the future of energy storage.

96 Room-temperature sodium metal batteries are impractical today because morphological in

97 Aqueous rechargeable batteries are promising solutions for large-scale energy

98 es as highly efficient sulfur hosts for Li-S batteries are reported here.

99 r stability compared with supercapacitors or batteries, are limited in applications due to their low

100 O2 as a potential cathode material for K-ion batteries as an alternative to Li technology.

101 A rechargeable zinc-air battery assembled in a decoupled configuration with the

102 Secondary batteries based on earth-abundant sodium metal anodes ar

103 Rechargeable batteries based on lithium (Li) metal chemistry are attr

104 Rechargeable batteries based on metallic anodes are of interest for f

105 Lithium-ion (Li-ion) batteries based on spinel transition-metal oxide electro

106 an all-stretchable-component sodium-ion full battery based on graphene-modified poly(dimethylsiloxane

107 tic ballasts" in a closed-loop concentration battery based on RED.

108 A lithium-sulfur battery based on this strategy exhibits long cycling lif

109 , offers a variety of novel opportunities in battery, biology, deep ultraviolet light emitting diodes

110 ral learning deficits in a touchscreen-based battery, but leads to increased adult cell proliferation

111 st cycling stability among all reported Mg/S batteries by suppressing polysulfide dissolution.

112 the dendrites and can extend the life of the battery by approximately five times.

113 demonstrate the application of the electron battery by stimulating a monolayer of cultured cells, wh

114 dence that the polysulfide shuttle in a Li-S battery can be stabilized by using electrocatalytic tran

115 mphasis on lithium-ion batteries, sodium-ion batteries, catalysis of hydrogen evolution, oxygen evolu

116 electrode materials of lithium or sodium ion batteries, catalysts for water splitting, and hydrogen e

117 Lithium-ion battery cathode materials have relied on cationic redox

118 d some of the issues, their pacer-integrated batteries cause new health risks and functional limitati

119 eneration under different tariff conditions, battery characteristics, and ownership scenarios using m

120 rence between marginal emission rates during battery charging and discharging.

121 -ion materials to investigate light-assisted battery charging.

122 3200 Wh L(-1) ) is among the highest of all battery chemistries (lower than Li/O2 and Mg/O2 but comp

123 New battery chemistries based on LiOH, rather than Li2 O2 ,

124 Most next-generation Li ion battery chemistries require a functioning lithium metal

125 In this work, a distinct battery chemistry that prevails in water-contaminated ap

126 Here we report a battery chemistry that utilizes magnesium monochloride c

127 vel generic method to understand the in situ battery chemistry without any further sample processing,

128 Solar rechargeable battery combines the advantages of photoelectrochemical

129 nalog differential amplifiers operating at a battery-compatible power supply voltage of 5 V with powe

130 Organic rechargeable batteries, composed of redox-active molecules, are emerg

131 Participants completed a questionnaire battery comprising measures of their exposure to various

132 ntification of gas evolution under realistic battery conditions.

133 In application to quasi-solid-state zinc-air batteries, CoO0.87 S0.13 /GN as a freestanding catalyst

134 Battery degradation was monitored using impedance spectr

135 sult from procedural inconsistencies in test battery design, but also from differences in how animals

136 and gamma-Fe2O3 utilizing miniature lithium-battery devices.

137 romising cathode material for lithium-sulfur batteries, displaying a high capacity of 520 mAh g(-1) a

138 Li-ion batteries dominate portable energy storage due to their

139 aterial for high-energy-density rechargeable batteries due to its favorable combination of negative e

140 eneration of high energy density lithium-ion batteries due to its high specific capacity (3,860 mAh g

141 /3Ti5/3O4), are appealing for application in batteries due to their negligible volume change and extr

142 ndidate for the next-generation rechargeable battery due to its highest specific capacity (3860 mA h

143 be higher than those of hybrid electric and battery electric vehicles.

144 nergy material, including as a lithium-based battery electrode candidate, due to its environmental fr

145 first time, we report a family of sodium-ion battery electrodes obtained by replacing stepwise the ox

146 emerging interface technologies ranging from battery electrodes to evaporation surfaces.

147 in photocatalysis, gas sensing and as Li-ion battery electrodes.

148 xture and morphology scenarios for different battery electrolytes.

149 waste rich in antimony, a component used in batteries, electronics, ammunitions, plastics, and many

150 In a lithium-ion battery, electrons are released from the anode and go th

151 To date, most known aqueous ion batteries employ metal cation charge carriers.

152 Consequently, a Li-metal battery employing a Li metal anode with the grafted skin

153 The Li-S battery equipped with the supramolecular capsules retain

154 most favoured choices for next-generation Li batteries, especially Li-S and Li-air systems.

155 ivity of the cathode, the as-prepared Li-CO2 batteries exhibit high reversibility, low polarization,

156 The battery exhibits reasonable electrochemical performance

157 ndicating it is not compatible with the real battery fabrication process.

158 ust to improve the energy density of lithium batteries for electric vehicle applications.

159 ical assessments were the Kaufman Assessment Battery for Children, second edition (KABC-II), and the

160 tile rank of </=5 on the Movement Assessment Battery for Children-Second Edition), and behavior probl

161 sts, promising a safe and long-life Li metal battery for high-energy applications.

162 lobal cognitive function with the Repeatable Battery for the Assessment of Neuropsychological Status

163 Using Repeatable Battery for the Assessment of Neuropsychological Status

164 ws for developing rechargeable iodine-carbon batteries free from the unsafe lithium/sodium metals, an

165 systems where their applications may include batteries, fuel cells, electrocatalytic water splitting,

166 esium and its application in rechargeable Mg batteries has received increasing attention owing to the

167 all-solid-state Li/polymer/LLZT-2LiF/LiFePO4 battery has a high Coulombic efficiency and long cycle l

168 This proof-of-concept of a membrane-free battery has an open circuit voltage of 1.4 V with a high

169 The lithium-air (Li-O2 ) battery has been deemed one of the most promising next-g

170 Rechargeable magnesium batteries have attracted considerable attention because

171 SnO2 -based lithium-ion batteries have low cost and high energy density, but the

172 Rechargeable potassium metal batteries have recently emerged as alternative energy st

173 Such batteries have the merit of low cost, innate safety, and

174 Redox flow batteries have the potential to revolutionize our use of

175 hermoelectrics), energy storage (lithium-ion batteries, hydrogen generation), emissive materials (pla

176 e key component of the fiber-shaped zinc-air battery, i.e., a bifunctional catalyst composed of atomi

177 been employed as solid-state electrolytes in batteries, improved thermoelectrics and fast-ion conduct

178 and generated a model GRN for the major gene batteries in heart morphogenesis.

179 considered as an alternative to lithium ion batteries in large-scale energy storage applications owi

180 d followed by a mask, and the Emotional Test Battery in which reaction times and performance accuracy

181 re we report a rechargeable magnesium/iodine battery, in which the soluble iodine reacts with Mg(2+)

182 icipants underwent a detailed neurocognitive battery, informant interviews, and adjudicated review to

183 le-layer capacitors (EDLCs) and rechargeable batteries is converging to target systems that have batt

184 y functionalized hybrid electrode for Zn-air batteries is discussed that requires no carbon.

185 ity of intercalating lithium in rechargeable batteries is limited (theoretically, 372 mAh g(-1)) due

186 in water-contaminated aprotic lithium-oxygen batteries is revealed.

187 The main advantage of redox flow batteries is their ability to decouple power and energy.

188 findings using the current in vitro testing battery is a major challenge to industry and regulatory

189 The lithium-sulfur (Li-S) battery is a promising high-energy-density storage syste

190 Discharge in the lithium-O2 battery is known to occur either by a solution mechanism

191 Rechargeable magnesium/sulfur battery is of significant interest because its energy de

192 The development of a competitive magnesium battery is plagued by the existing notion of poor magnes

193 application of lithium salts in lithium-ion batteries leading to a fundamental shift in the lithium

194 formation of insulating Li2 CO3 , making the battery less rechargeable.

195 es is converging to target systems that have battery-level energy density and capacitor-level cycling

196 Li ion battery (LIB) and electrochemical capacitor (EC) are con

197 ive metal-ion battery systems to lithium-ion batteries (LIBs) due to the abundance and low cost of po

198 ed for use as anode materials in lithium-ion batteries (LIBs) for the first time.

199 Li-ion batteries (LIBs) were fabricated to test the utility of

200 ce of SnO2 -based electrodes for lithium-ion batteries (LIBs).

201 , a pacemaker with less than 1 month left of battery life reset to ventricular inhibited pacing and c

202 hode and the lithium anode in lithium-sulfur batteries (LSBs).

203 ditional savings could be seen from changing battery manufacturing location and ensuring end of life

204 g, which can preserve the original nature of battery materials or electrodeposited materials.

205 xplain the improved properties of catalysts, battery materials, plasmonic materials, etc.

206 atalytic materials and anion-redox chalcogel battery materials.

207 gnition in Schizophrenia Consensus Cognitive Battery (MCCB) in cognitive impairment associated with s

208 schizophrenia (MATRICS) consensus cognitive battery (MCCB), especially focusing on reasoning and pro

209 ts hadrosauriform relatives possessing tooth batteries of many small teeth, Lanzhousaurus utilized a

210 The battery of 10 tests was administered online to 1,367 twi

211 We performed a battery of analyses for these five loci, as well as join

212 val in most environments, bacteria express a battery of anti-phage defences including CRISPR-Cas, res

213 ls (N = 347, 18-59 years of age) completed a battery of behavioral measures, psychiatric assessment,

214 KO mice, NRG2 KOs performed abnormally in a battery of behavioral tasks relevant to psychiatric diso

215 coupled with mass spectrometry (HXMS) and a battery of biochemical and biophysical tools to investig

216 insically disordered regions, we conducted a battery of biophysical experiments on the EGFR and HER3

217 NC to formulate given sequence samples via a battery of cross-covariance and auto-covariance transfor

218 The mRNA expressions of a battery of genes related to biotransformation, oxidative

219 erein, we describe a process that utilizes a battery of in-house quantitative structure-activity rela

220 linical evaluation including a comprehensive battery of language tests.

221 I, He et al. report on their employment of a battery of lineage-tracing tools to address the developm

222 Here, we describe a battery of mutagenic cassettes that can be applied in co

223 )F-FDG PET brain imaging and a comprehensive battery of neuropsychological tests were performed in 10

224 uilibrium statistics, recombination rates, a battery of neutrality tests, and population differentiat

225 lationships between spatial activation and a battery of objective out-of-scanner assessments that ind

226 this work, we investigate the effect on the battery of removing 99.1% of the total stored energy.

227 schizophrenia spectrum disorder completed a battery of tests of executive function and underwent dif

228 ics and spatial anxiety as part of an online battery of tests.

229 Strikingly, PRDM13 also ensures a battery of ventral neural tube specification genes such

230 All-Organic non-aqueous redox-flow batteries offer a solution, but suffer from rapid capaci

231 ield of nonaqueous multivalent intercalation batteries offers a promising way to overcome safety, cos

232 eld ultrasound equipment that is compact and battery operated, and handheld echocardiography can be r

233 alizes electrons during lithiation events in battery operations-namely, through-space electron deloca

234 lithiation additive for existing lithium-ion batteries or a replacement for lithium metal in Li-O2 an

235 such applications, the energy available from batteries or the power available from energy harvesters

236 ratings, a comprehensive neuropsychological battery, overnight hourly blood sampling for cortisol an

237 table output and a series connected bendable battery pack with higher voltage is also demonstrated.

238 ogens, and demonstrate substantial Li-oxygen battery performance improvement by porosity control.

239 roperties are highly desirable for improving battery performance.

240 Potassium-ion batteries (PIBs) are interesting as one of the alternati

241 , and high energy densities, all-solid-state batteries play a key role in the next generation energy

242 Lithium polysulfide batteries possess several favorable attributes including

243 e-liquids were used with various vaporizers, battery power settings and vaping regimes.

244 During the Emotional Test Battery, reaction times decreased to identification of p

245 otentially useful for rechargeable metal-air batteries, regenerative fuel cells, and other important

246 ial, leading to a single output voltage in a battery, remains a fundamental challenge in this popular

247 ties for the development of long-term Li-air batteries reusable under ambient conditions, and the uti

248 such conditions, a significant amount of the battery's energy is stored; in the event of mismanagemen

249 meability of redox-active species across the battery's membrane.

250 ode's electrical conductivity to improve the battery's power capability, as well as contribute to the

251 y important applications such as fuel cells, batteries, sensors, and catalysis.

252 The next generation of high-performance batteries should include alternative chemistries that ar

253 a result, the rechargeable magnesium/iodine battery shows a better rate capability (180 mAh g(-1) at

254 in PIBs, slightly higher than for sodium-ion batteries (SIBs) (0.01 V), and well above the plating po

255 ion, with particular emphasis on lithium-ion batteries, sodium-ion batteries, catalysis of hydrogen e

256 ures included the Short Physical Performance Battery (SPPB) and Short Portable Sarcopenia Measure (SP

257 s are underway to develop all-solid-state Li batteries (SSLiBs) toward high safety, high power densit

258 ell capacity, and further demonstrate a flow battery system based on the reactivation approach.

259 A bendable integrated solar cell-battery system charged by light with stable output and a

260 o the marginal electricity grid in Kenya, PV-battery systems save 80-88%.

261 ompared to small-scale diesel generators, PV-battery systems save 94-99% in the above categories.

262 eresting as one of the alternative metal-ion battery systems to lithium-ion batteries (LIBs) due to t

263 aradigm for multi-ions-based electrochemical battery technologies and applications.

264 t anode potential is extremely attractive to battery technologies, but infinite volume change during

265 To improve lithium and sodium ion battery technology, it is imperative to understand how t

266 m a universal anode approach for any aqueous battery technology.

267 nsity limitations of state-of-the-art Li-ion battery technology.

268 Here we report a full-cell battery that contains a lithiated Si/graphene anode pair

269 We report a membrane-free battery that relies on the immiscibility of redox electr

270 (fuel cells, water splitting, and redox flow batteries) that involve multiple phase reactions.

271 ndard carbonate-based electrolyte for Li-ion batteries, the solid electrolyte interphase (SEI) formed

272 Green redox flow batteries: The development of environmentally benign sus

273 Unlike typical batteries, these systems are soft, flexible, transparent

274 in we focus on the Li bond chemistry in Li-S batteries through sophisticated quantum chemical calcula

275 Ni3 FeN bifunctional catalyst enables Zn-air batteries to achieve a long-term cycling performance of

276 an all other reported rechargeable magnesium batteries using intercalation cathodes.

277 development of high-performance solid-state batteries using these exceptional materials, the major c

278 Changes in lead impedance, pacing threshold, battery voltage, and P-wave and R-wave amplitude exceede

279 A neuropsychological test battery was used to assess cognition.

280 The MATRICS Consensus Cognitive Battery was utilized to measure cognitive performance in

281 damental electrochemistry of the lithium-ion battery, we envision a cell that can generate a current

282 ore was measured, and mood and psychological batteries were administered under four stimulation condi

283 Conventional batteries were not designed with these criteria in mind.

284 al to the performance of aprotic lithium-air batteries, whereas this view is challenged by recent con

285 eter-sized electronics devices without using batteries, which compromise biocompatibility and long-te

286 Recently, interest in aluminium ion batteries with aluminium anodes, graphite cathodes and i

287 They are used in non-rechargeable batteries with anodes like zinc.

288 chemistry of iodine to produce iodine-carbon batteries with high reversible capacities.

289 Herein, knittable fiber-shaped zinc-air batteries with high volumetric energy density (36.1 mWh

290 LiPF6-based electrolyte solutions of Li-ion batteries with lithium manganate spinel positive and gra

291 , bendable lithium-sulfur and lithium-oxygen batteries with long cycling stability are realized.

292 a viable approach to develop lithium-sulfur batteries with practical energy densities exceeding that

293 Electron batteries with the capability to generate a tunable ioni

294 V alkaline anthraquinone/ferrocyanide redox battery with a high ideal solar-to-chemical conversion e

295 Here, we demonstrate a rechargeable Li-CO2 battery with a high reversibility by using B,N-codoped h

296 e development of the first rechargeable Mg/S battery with a MgTFSI2 /MgCl2 /DME electrolyte (DME=1,2-

297 uring lithiation and de-lithiation of a Li-S battery with CuS as the multi-functional cathode additiv

298 k and spatial working memory tasks (CogState Battery), without significantly attenuating ketamine-ind

299 h a Registry for Alzheimer's Disease (CERAD) battery (Word List Learning, World List Delayed Recall,

300 ief Assessment of Cognition in Schizophrenia battery yielded a single factor (54% variance explained)